World Applied Sciences Journal 6 (): 3-8, 202 ISSN 88-4952 IDSI Publications, 202 Synthesis and Swelling Behavior of Carrageenans-Graft-Poly(Sodium Acrylate)/Kaolin Superabsorbent Hydrogel Composites Mohammad Sadeghi, Nahid Ghasemi and Monavar Kazemi Department of Chemistry, Science Faculty, Islamic Azad University, Arak Branch, Arak, Iran Abstract: In the present paper, a novel superabsorbent hydrogel composite based on carrageenan have been prepared via graft copolymerization of acrylic acid (AA) in the presence of kaolin powder using methylenebisacrylamide (MBA) as a crosslinking agent and ammonium persulfate (APS) as an initiator. The certain variables of the graft copolymerization (i.e. the monomer, the initiator and the crosslinker concentration as well as kaolin/carrageenan weight ratio) affected on the ultimate water-swelling capacity were optimized. The composite structure was confirmed using FTIR spectroscopy. A new absorption band at 707 cm in the composite spectrum confirmed kaolin-organic polymer linkage. The effect of kaolin amount and MBA concentration showed that with increasing of these parameters, the water absorbency of the superabsorbent composite was decreased. Key words: Carrageenan Acrylic acid Superabsorbent Methylenebisacrylamide Composite INTRDUCTIN because of their small particle size and intercalation properties [6-7]. Mineral powders are hydrated layered Vinyl graft copolymerization onto polysaccharide aluminosilicate with reactive-h groups on the surface. backbones is a well-known method for synthesis of The interaction of mineral powders, reactive site of natural natural-based superabsorbent hydrogels. The first polymers and monomers result in a superabsorbent industrial superabsorbent hydrogel, hydrolyzed starch- composite. Superabsorbent composites based on graft-polyacrylonitrile, was synthesized using this synthetic polymers [0-] or natural polymers [2] have method. These biopolymer materials are crosslinked been reported. hydrophilic polymers, capable of absorbing large Carrageenans are relatively new polysaccharides to quantities of water, saline or physiological solutions. synthesize of natural-based SAPs. These linear sulfated They are widely used in many fields such as hygienic, polysaccharides that are obtained from certain species of cosmetics and agriculture [-5]. red seaweeds are composed of D-galactose and 3,6- Because of their exceptional properties, i.e. anhydrogalactose units [3]. The types of carrageenans biocompatibility, biodegradability, renewability and differ only in the position and number of ester sulfate non-toxicity, polysaccharides and proteins are the groups. Following a continuous research on modification main part of the natural-based superabsorbent of carrageenans [4], in this work, we attempt to hydrogels. The higher production cost and low gel synthesize and characterize new superabsorbent strength of these superabsorbents, however, restrict composites based on carrageenan in the presence of their application widely. To improve these limitations, kaolin particles. The preparation of the biopolymer-based inorganic compounds with low cost can be used. The superabsorbent composites can also improve the introduction of inorganic fillers to a polymer matrix mechanical properties of materials and can lower the cost increases its strength and stiffness properties. of the finished product compared with the synthetic Among inorganic compounds, special attention has counterparts as well as providing biodegradable been paid to clay minerals in the field of nanocomposites characteristics. Corresponding Author: Mohammad Sadeghi, Department of Chemistry, Science Faculty, Islamic Azad University, Arak Branch, Arak, Iran. Tel: +98-86-367007, Fax: +98-86-367007. 3
World Appl. Sci. J., 6 (): 3-8, 202 Experimental Materials: Kappa-carrageenan ( C, from Condinson Co., Denmark), was used as received. Acrylic acid (AA, Merck), was used after vacuum distillation. Ammonium persulfate (APS, Merck) was used without purification. Methylene bisacrylamide (MBA, Fluka), was used as received. All other chemicals were of analytical grade. The accuracy of the measurements was ±3%. Infrared Spectroscopy: FTIR spectra of samples were taken in KBr pellets using an ABB Bomem MB-00 FTIR spectrophotometer. RESULTS AND DISCUSSIN Superabsorbent Composite Synthesis: Synthesis of the Synthesis and Characterization: The superabsorbent hydrogel, C-g-PAcA/kaolin composite, was carried out composite was prepared by graft copolymerization of using APS as an initiator and MBA as a crosslinker in an acrylic acid onto carrageenan in the presence of a aqueous medium. A general procedure for crosslinking crosslinking agent and powdery kaolin. Ammonium graft copolymerization of AcA onto C was conducted as persulfate was used as an initiator. The persulfate is follows. C (.0 g) was added to a three-neck reactor decomposed under heating and produced sulfate anionequipped with a mechanical stirrer (Heidolph RZR 202, radicals that abstract hydrogen from one of the functional three blade propeller type, 350 rpm), including 35 ml groups in side chains of carrageenan backbones. So, this deoxygenated doubly distilled water. The reactor was persulfate-saccharide redox system results in active immersed in a thermostated water bath preset at desired centers capable to radically initiate polymerization of temperature (65 C). After complete dissolution of C to acrylic acid led to a graft copolymer. Since a crosslinking form a homogeneous solution, various amounts of kaolin agent, e.g. MBA, is presented in the system, the powder (0.75-0.25 g) were added to the solution and copolymer comprises a crosslinked structure. allowed to stir for 0 min. Then, APS initiator (0.05-0.4 g, For identification of the hydrogel, infrared dissolved in 5 ml water) was added to the reaction mixture spectroscopy was used. Figure shows the IR and the mixture was stirred for 0 min. MBA (0.05-0.2 g, spectroscopy of C and C-g-PAcA hydrogel dissolved in 5 ml water) and AcA (.0-5.0 g, completely composite. The bands observed at 84, 98, 02 and neutralized with NaH) were poured into the reactor. All 222 cm can be attributed to D-galactose-4-sulfate, of the reactions were carried out at 70 C under an argon 3,6-anhydro-D-galactose, glycosidic linkage and ester gas atmosphere and the reaction mixture was sulfate stretching of C, respectively (Fig. a). The continuously stirred (300 rpm) for h. At the end of the broad band at 300-3600 cm is due to stretching reaction, the gelly product was poured in ethanol (300 ml) of-h groups of C. The IR spectrum of the and allowed to dewater for 24 h. Then, the product was hydrogel composite, C-g-PAcA (Fig. b) shows filtered and washed with 00 ml ethanol. The filtered three new characteristic absorption bands at product was dried in an oven at 50 C for 0 h. After 707, 542 and 402 cm verifying the formation of grinding, the powdered superabsorbent composite was graft copolymer product. These peaks attributed to stored away from moisture, heat and light [5]. carbonyl stretching of the carboxylic acid groups and symmetric and asymmetric stretching modes of Swelling Measurements Using Tea Bag Method: The tea carboxylate anions, respectively [5-6]. Combination bag (i.e. a 00 mesh nylon screen) containing an of absorption of the carboxylate and alcoholic -H accurately weighed powdered sample (0.5 ± 0.00 g) was stretching bands is appeared in the wide range of immersed entirely in 200 ml distilled water and allowed to 2550-3600 cm. soak for 3 h at room temperature. The sample particle sizes The absorption band at 707 cm can be were 40 to 60 meshes (250-350µm). The tea bag was hung corresponding to the ester groups that can be formed up for 5 min in order to remove the excess solution. The during the graft polymerization reaction. The carboxylate equilibrium swelling (ES) was calculated according to groups of the grafted poly(acrylic acid) can be react with following equation: the-h groups on the kaolin surface. The replacement of- H groups in the surface of kaolin by carboxylate anions Weight of swollen gel Weight of dried gel ES( g / g) = () results in the ester formation. The reaction can be shown Weight of dried gel as follows: 4
World Appl. Sci. J., 6 (): 3-8, 202 Si H + - -H - Si Surface of kaolin Carboxylate anions Ester As shown in this figure, the absorption bands of-h of kaolin at 3628-3674 cm are disappeared. ptimization of Effecting Parameters onto Swelling Effect of the Monomer Concentration on Swelling: Capacity The swelling capacity as a function of monomer Effect of MBA Concentration on Swelling: The effect of concentration was investigated and results shown in crosslinker concentration (C c) on swelling capacity of Figure 3. According to this figure, the absorbency is crosslinked carrageenan-g-poly(acrylic acid)/kaolin increased with increasing the acrylic acid concentration hydrogel was investigated. As shown in Figure 2, more from 0.2 up to 0.42 mol/l and then, it is decreased values of absorbency are obtained by lower C c. Such a considerably with a further increase in the amount of well-known behavior reported by pioneering scientists monomer. The maximum absorbency (2 g/g) is obtained [7,5]. In fact, higher C c decrease the free space between at 0.42 mol/l of the monomer. The initial increase in the copolymer chains and consequently the resulted swelling capacity can be attributed to (a) greater highly crosslinked rigid structure can not be expanded availability of monomer molecules in the vicinity of the and hold a large quantity of water. This power law chain propagating sites of gelatin macroradicals and (b) behavior between swelling capacity and MBA increase the hydrophilicity of the hydrogel originated concentration (Eq. 2) was conducted from Figure 2. from higher AcA content that, in turn, causes a stronger -n Swelling capacity K [MBA] (2) affinity for more absorption of water. The swelling-loss after the maximum may be attributed to (a) preferential homopolymerization over graft copolymerization, (b) The K and n in Eq. 2 are constant values for an increase in viscosity of the medium which restricts the individual superabsorbent. The n value represents the movement of free radicals and monomer molecules and (c) extent of the sensitivity of the hydrogel to the crosslinker the enhanced chance of chain transfer to monomer content, while the K value gives an amount useful for molecules. Such behaviors are reported by other comparing the extent of swelling versus fixed crosslinker investigators [6-8]. content. The K=3.89 and n=0.53 is obtained from the curve fitted with Eq. 2. Transmittance/Wavenumber (cm ) Fig. : FTIR spectra of (a) pure carrageenan and (b) carrageenan-g-poly(acrylic acid)/kaolin composite. 5
World Appl. Sci. J., 6 (): 3-8, 202 Fig. 2: Effect of the crosslinker concentration on water Fig. 4: Effect of initiator concentration on water absorbency of the superabsorbent composite absorbency of the superabsorbent composite (Reaction conditions: carrageenan=kaolin=0.02 wt (Reaction conditions: carrageenan= kaolin=0.02 wt %, AANa 0.5 mol/l, APS 0.05 mol/l, 70 C, h). %, MBA 0.00582mol/L, AANa0.47mol/L, 70 C, h). Fig. 3: Water absorbency dependency of the Fig. 5: Effect of kaolin/carrageenan weight ratio on water superabsorbent composite on the monomer absorbency of the hydrogel composite (Reaction (sodium acrylate) concentration (Reaction conditions: MBA 0.00582 mol/l, AANa 0.47 mol/l, conditions: carrageenan= kaolin=0.02 wt %, MBA APS 0.09 mol/l, 70 C, h). 0.00582 mol/l, APS 0.05 mol/l, 70 C, h). backbone is decreased at lower concentrations than Effect of APS Concentration on Swelling: The influence 0.09 mol/l which, in turn, resulting in lower graft of initiator concentration on final swelling capacity of the polymerization extent and consequently lower final hydrogel has been studied by varying the APS water absorbency. Subsequent swelling loss can be concentration from 0.002 to 0.033 mol/l (Figure 4). explained on the basis of (a) an increase in terminating Maximum swelling (34 g/g) was obtained at 0.09 mol/l step reaction via bimolecular collision, which is referred to of initiator concentration. More or less than this as self-crosslinking by Chen and Zhao [9] and (b) the concentration gives hydrogel with decreased swelling decrease in molecular weight (MW) of grafted poly acrylic capacity. The number of active free radicals on the gelatin acid of the hydrogel causes to decrease swelling value. 6
World Appl. Sci. J., 6 (): 3-8, 202 The latter reason is due to the inverse relationship between MW and initiator concentration. Also, the free radical degradation of gelatin backbones by sulfate radical-anions is an additional reason for swelling-loss at higher APS concentration. The proposed mechanism for this possibility is reported in the previous work [8-9]. A similar oxidative degradation of chitosan chains by potassium persulfate is recently reported by Hsu et al. [2]. Effect of Kaolin/ Carrageenan Weight Ratio on Swelling: The effect of kaolin content on the water absorbency of the composite was studied (Figure 5). The kaolin/carrageenan weight ratio was varied from 0.25 to 2.50, while other reaction variables were constant. The effect of kaolin amount on water absorbency is similar to MBA influence on absorbency. Figure 5 indicates that the water absorbency of the superabsorbent is decreased with increasing the kaolin amount incorporated in the composite structure. The clay in the polymerization reaction may be acts via two ways: (a) kaolin particles acts as a crosslinking agent (it means that carboxylate groups of sodium poly(acrylate) chains react with kaolin as obviously proved by FTIR spectra (Fig. )) and (b) kaolin particles prevent the growing polymer chains through a chain transfer mechanism [5,2]. CNCLUSIN A novel natural-based superabsorbent composite polymer was prepared by graft copolymerization of acrylic acid onto carrageenan backbones in the presence of a crosslinking agent. The resultant superabsorbent composite had a large degree of water absorbency. The study of FTIR spectra shows that in the composite spectrum a new absorption band at 707 cm was appeared that attributed to the ester formation from replacement of hydroxyl groups of kaolin with grafted carboxylate anions onto polysaccharide backbones. The optimum reaction conditions was achieved at MBA 0.00582 mol/l, initial AA 0.42mol/L, APS 0.09 mol/l and kaolin/carrageenan 0.25 wt %. The effect of the kaolin amount and MBA concentration showed that with increasing of these parameters, the water absorbency of the superabsorbent composite are decreased. The hydrogel composites will most probably posses higher biodegradability (due to the carrageenan part) and higher swollen gel strength (due to the inorganic parts). The latter properties are of the subjects under consideration in our laboratory. REFERENCES. Buchhulz, F.L. and N.A. Peppas, 994. in Superabsorbent Polymer Science and Technology, ACS Symposium Series 573, American Chemical Society, Washington, DC. 2. Buchholz, F.L. and A.T. Graham, 997. in Modern Superabsorbent Polymer Technology, Wiley, New York. 3. Hennink, W.E. and C.F. Van Nostrum, 2002. Novel Crosslinking Methods to Design Hydrogels, Adv. Drug Deliv. Rev., 54: 3-36. 4. Peppas, L.B. and R.S. Harland, 990. Absorbent Polymer Technology, Elsevier, Amsterdam. 5. Po, R., 994. Water-absorbent Polymers, A Patent Survey. J. Macromol. Sci-Rev. Macromol. Chem. Phys., C34: 607. 6. Hoffman, A.S., 996. Polymeric Materials Encyclopedia, Vol. 5, Salamone JC (ed). CRC Press: Boca Raton, FL, 3282. 7. Lin, J., J. Wu, Z. Yang and M. Pu, 200. Synthesis and Properties of Poly(acrylic acid)/mica Superabsorbent Nanocomposite, Macromol. Rapid Commun., 22: 422-424. 8. Lin, J., J. Wu, Z. Yang and M. Pu, 200. Synthesis and Properties of Poly (acrylic acid)/montmorillonite Superabsorbent composites, Polymers and Polymer Composites, 9: 469-47. 9. Wu, J., J. Lin, M. Zhou and C. Wei, 2000. Synthesis and Properties of Starch-g-Polyacrylamide/Clay Superabsorbent composite, Macromol. Rapid Commun., 2: 032-034. 0. Wu, J., Y. Wei, J. Lin and S. Lin, 2003. Study on Starch-g-Acrylamide/Mineral Powder Superabsorbent Composite, Polymer, 44: 653-6520.. Kirk, R.E. and D.F. thmer, 992. Encyclopedia of Chemical Technology, Vol. 4, J.I. Kroschwitz and M. Howe-Grant (eds). John Wiley and Sons: New York, pp: 942. 2. Hsu, S.C., T.M. Don and W.Y. Chiu, 2002. Free Radical Degradation of Chitosan with Potassium Persulfate. Polym. Degrad Stab., 75: 73. 3. Lim, D.W., H.S. Whang and K.J. Yoon, 200. Synthesis and Absorbency of a Superabsorbent from Sodium Starch Sulfate-g-Polyacrylonitrile. J. Appl. Polym. Sci., 79: 423. 4. Barbucci, R., A. Maganani and M. Consumi, 2000. Swelling Behavior of Carboxymethylcellulose Hydrogels in Relation to Cross-linking, ph and Charge Density. Macromolecules, 33: 7475. 7
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